CN102227591A - Material mixture for producing fireproof material, fireproof molded body and method for manufacturing thereof - Google Patents
Material mixture for producing fireproof material, fireproof molded body and method for manufacturing thereof Download PDFInfo
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- CN102227591A CN102227591A CN2009801474036A CN200980147403A CN102227591A CN 102227591 A CN102227591 A CN 102227591A CN 2009801474036 A CN2009801474036 A CN 2009801474036A CN 200980147403 A CN200980147403 A CN 200980147403A CN 102227591 A CN102227591 A CN 102227591A
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
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- C04B35/00—Shaped ceramic products characterised by their composition; Ceramics compositions; Processing powders of inorganic compounds preparatory to the manufacturing of ceramic products
- C04B35/622—Forming processes; Processing powders of inorganic compounds preparatory to the manufacturing of ceramic products
- C04B35/626—Preparing or treating the powders individually or as batches ; preparing or treating macroscopic reinforcing agents for ceramic products, e.g. fibres; mechanical aspects section B
- C04B35/62605—Treating the starting powders individually or as mixtures
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- C04B2235/32—Metal oxides, mixed metal oxides, or oxide-forming salts thereof, e.g. carbonates, nitrates, (oxy)hydroxides, chlorides
- C04B2235/3217—Aluminum oxide or oxide forming salts thereof, e.g. bauxite, alpha-alumina
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- C04B2235/3231—Refractory metal oxides, their mixed metal oxides, or oxide-forming salts thereof
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Abstract
The invention relates to a material mixture for producing a fireproof material, comprising spinel and zirconium oxide and a coarse-grained fraction with a weight fraction of greater than 50% and a fine-grained fraction, wherein the coarse-grained fraction comprises coarse grains with dimensions larger than 20 microns and the fine-grained fraction comprises fine grains with dimensions smaller than 20 microns.
Description
The present invention relates to be used to prepare the material blends of refractory material.The invention still further relates to the fire-resistant formed body that is used for the high-temperature gas reactor, especially for the heat shield element of gas turbine, and the preparation method who relates to fire-resistant formed body.
For the wall of the high-temperature gas reactor of carrying hot gas, the wall of the combustion chamber in the gas turbine device for example, their supporting structure need have the heat shielding of opposing hot gas invasion and attack.Heat shielding can be for example by the hot gas lining of Actual combustion locular wall, and for example the form with ceramic heat shielding provides.Such hot gas lining is made of a plurality of metals or ceramic heat shield element usually, and they are the lining on chamber wall surface.Because heat-resisting quantity, corrosion resistance height and the thermal conductivity of ceramic material are low, the ceramic material metal material of comparing is more suitable for constituting the hot gas lining.Pottery heat shielding (Hitzeschild) for example is recorded among EP 0 558540 B1.
The temperature difference (between the maximum temperature when environment temperature when for example gas turbine equipment is stopped work and full load) can appear in thermal expansion character and the operating process usually because material generally all has; owing to the reason of the expansion that depends on temperature must be guaranteed the thermal fluidity of thermal fluidity, particularly ceramic heat shielding, thereby can not produce the thermal stress of destroying heat shielding because of the obstruction of the expansion that depends on temperature.For this reason, between each heat shield element, exist dilatation joint (Dehnspalt) to allow the thermal expansion of heat shield element.For security reasons, though dilatation joint when the hot gas of maximum temperature also from incomplete closure.Thereby must guarantee that hot gas flow to the abutment wall structure of combustion chamber without dilatation joint.Enter to prevent hot gas in order to intercept dilatation joint, wash through the obstruct air (Sperrluft) that flows to inside, combustion chamber commonly used.Usually as intercepting air, it also is used as the cooling air of the clamping element of cooling clamping heat shield element to air simultaneously, or the like, the result causes formation temperature gradient in the fringe region of heat shield element.By dilatation joint being washed the encirclement side of having cooled off the qualification seam, the i.e. cold side of heat shield element (Kaltseite) with intercepting air.On the other hand, a large amount of inputs of hot gas are gone up generation in the hot side (Hei β seite) of heat shield element.Thereby the inside of heat shield element produces three-dimensional Temperature Distribution, it is characterized by the temperature drop of hot side to the central point of cold side and heat shield element to the edge.Therefore, particularly in the situation of ceramic heat shield element, even there is not contact between the adjacent heat shielding element, will produce stress on hot side, it will cause forming crackle, and therefore influence the service life of heat shield element unfriendly.
Heat shield element in the gas-turbine combustion chamber generally constitutes flat shape, and setting is parallel to supporting structure.The thermograde that changes perpendicular to the supporting structure surface only causes lower thermal stress at this, as long as can without hindrance inside from the combustion chamber to front curve that go at the ceramic heat shield element of installment state.
Be parallel to the thermograde that supporting structure changes, as the thermograde that changes from the heat shield element outer surface to the heat shield element center, will cause thermal stress to increase rapidly, this is because the rigidity of the sheet geometry of the deformation of parallel its maximum projection plane.This will cause: because the cold edge of outer surface is because the less pulling force than the zone, thermal center (-tre) that is subjected to experiencing big thermal expansion of its thermal expansion.This pulling force will cause forming from the edge of heat shield element when surpassing the strength of materials and begin along the crackle of heat shield element central area direction.
Crackle has reduced the bearing cross-section of heat shield element.Crackle is long more, and the remaining bearing cross-section of heat shield element is more little.The mechanical load that produces in the operating process of gas turbine equipment will cause thermal induction crackle lengthening, and this will further reduce remaining cross section and may force the replacing heat shield element.When quickening, the vibration of the chamber wall that this mechanical load for example causes in combustion vibration (for example vibration in the burnt gas) takes place.
In order to reduce the requirement that intercepts air and therefore to reduce heat-induced stress in the heat shield element, EP1302723A1 proposes to provide flow barrier in dilatation joint.This also can reduce the thermograde in the fringe region.Yet it is not always possible introducing flow barrier, has increased the complexity of heat shielding yet.
In addition, when being subjected to heavy corrosion and influencing, heat shield element will cause being subjected to the spillage of material of material lifetime restriction.The corrosion load pressure that the spillage of material that takes place in the situation of ceramic heat shield element causes owing to the hot gas of the back sintering (Nachsintern) on burn into surface and high-quality flux.Usually maximum spillage of material occurs in hot gas flow velocity highest point.For the ceramic heat shielding of often using now by corundum with glassy phase and mullite preparation, the main cause of spillage of material is two reactions, i.e. first reaction is that mullite decomposes and second reaction is grain growth and back sintering.The steam that exists in the hot gas causes mullite (3Al
2O
3* 2SiO
2Or 2Al
2O
3* 1SiO
2) and glassy phase resolve into corundum (Al
2O
3) and the oxide (SiO of silicon
x).Then, be present in the lip-deep corundum of heat shield element, not only in the matrix of heat shield element but also in the corrosion layer of mullite particle, demonstrate grain growth and sintering.Grain growth and sintering increase along with continuing of operation.Along with the increase of gas turbine startup number, can weaken because of micro-crackization in the surface.Therefore, surface particles will be carried secretly (mitreissen) by the high-quality flux, thereby cause corrosion.The result is subject to corrosion the service life of heat shield element, must change heat shield element prematurely thereby force.In addition, in the situation of heavy oil operating gas turbine, add magnesia as inhibitor, it causes the corrosion wear of heat shield element equally.This is to cause as product owing to the reaction of the corundum in the heat shield element and the magnesia in the inhibitor generates spinelle.This also causes shorten service life, need change heat shield element prematurely.
DE 27 45 461 discloses a kind of magnesium aluminate spinels (MgAl that contains
2O
4) highly refractory stone material, it contains adhesive and the extremely fireproof filler of 27 weight % nearly of aluminium oxide, 1~9 weight % of magnesium aluminate spinels, 2~8 weight % of 70~93 weight %.Filler specifically is chromium oxide (III) (Cr
2O
3) and barium zirconate (CaZrO
3).In addition, can add the fusion spinelle, the crystal grain of founding spinelle for example, thus improve corrosion resistance and thermal shock resistance.DE2745461 has put down in writing the low material of CaO content, but still contain can detected SiO for they
2Composition.
DE 27 38 247 has put down in writing refractory alumina cement, and it can comprise magnesium aluminate spinels.The adding adhesive helps the moulding of alumina cement.In addition, product can be in use sintering, thereby saved the burning cost.Yet the defective of this material is that its corrosion resistance in corrosive gas and/or fusion environment is obviously poorer.
DE 102 54 676 A1 have put down in writing the refractory formed body, and its structure contains the zirconia (ZrO of (counting based on gross weight) 80~95%
2) and 5~20% magnesium aluminate spinels.Add magnesium aluminate spinels in order to produce better thermal shock resistance.
Optional method comprises use metal fever shielding element.Though the metal fever shielding element can be resisted temperature fluctuation and machinery meets better than ceramic heat shield element, but, for example in gas-turbine combustion chamber, the metal fever shielding need be carried out complicated cooling, and this is because the metal fever shielding element has higher thermal conductivity than ceramic heat shield element.In addition, the metal fever shielding element is easier to be corroded, and because their temperature stabilities are littler, thus they that works bears high temperature not as ceramic heat shield element.
Thereby first purpose of the present invention provides the material blends that is used to prepare fire-resistant formed body, and it is particularly useful for making the heat shield element that is used for gas turbine.Second purpose of the present invention provide be used to prepare fire-resistant formed body, as the favorable method of the heat shield element that is used for gas turbine.At last, the 3rd purpose of the present invention provides the favourable formed body that is used for the high-temperature gas reactor, for example the heat shield element used of gas turbine.
First purpose is by the material blends realization that is used to prepare refractory material of claim 1, and second purpose is by the method realization that is used to prepare fire-resistant formed body of claim 6, and the 3rd purpose realizes by the fire-resistant formed body of claim 12.Dependent claims comprises favourable embodiment of the present invention.
The material blends of the present invention that is used to prepare refractory material comprises spinelle (Spinell) and zirconia (Zirkonoxid), and the zirconia that particularly has monoclinic crystal structure also is known baddeleyite.It contains greater than the coarse component of 50 weight % (Grobkornanteil) and fine fraction (Feinkornanteil).Coarse component comprises the particle of size greater than 20 μ m, the particle of preferred 20 μ m~6mm and the particularly particle of 100 μ m~6mm, and fine fraction comprises the particulate of size less than 20 μ m.At this, especially, can have magnesium aluminate spinels (MgAl as coarse component
2O
4) and/or sintering spinelle (Sinterspinell) and/or fusion spinelle (Schmelzspinell).The sintering spinelle means cracked (herunterbrochen) spinelle through sintering to desired particle size herein, and the fusion spinelle means by the spinelle molten mass preparation and that then be broken to desired particle size.Especially, can have zirconia as fine fraction.In addition, also can have magnesium aluminate spinels and/or sintering spinelle and/or fusion spinelle as fine fraction.
Magnesium aluminate spinels in coarse component and fine fraction all can comprise the aluminium oxide (Al of 66~78 weight % especially
2O
3) and the magnesia (MgO) of 22~34 weight %.The weight quota of the magnesium aluminate spinels in the fine fraction of material blends is preferably 30~100%, and zirconic weight quota is 0~70% in the fine fraction.Especially, the weight quota of the magnesium aluminate spinels in the fine fraction of material blends is 70~100%, and the zirconic weight quota in the fine fraction is 0~30%, and especially, zirconic weight quota can be for greater than 12%.
Use material blends of the present invention can prepare the ceramic material of thermal-shock resistance and corrosion resistance, this ceramic material is particularly useful for making the heat shield element that fire-resistant formed body for example is used for gas turbine.Zirconia in the material blends is used for increasing corrosion resistance and particularly by forming micro-crack to obtain high anti-heat exchange property at matrix.Generally, so this material blends can be used to prepare the heat shield element of fire-resistant formed body, particularly gas turbine, and it had than the fire-resistant formed body of routine longer service life.Especially, prevent the decomposition of mullite (Mullits) and corundum by using spinelle, thereby keep basic heat shielding performance.More the result of long life is that assay intervals is longer, and this has reduced the running cost of gas turbine.Yet, be used for the shaped article of power industry, metallurgical industry, auto industry, glass and cement industry and chemical industry and not shaped article can prepare by material blends.The material according to the invention mixture specifically also can not use the adhesive of calcic to process.
According to a second aspect of the invention, provide be used to prepare fire-resistant formed body, especially for the method for the heat shield element of high-temperature gas reactor (as gas-turbine combustion chamber).Used the material according to the invention mixture in the methods of the invention.In described material blends, add the auxiliary material at least a dispersant and/or at least a organic basis or inorganic basis, thereby obtain plastic material (formbar Masse).Then this plastic material is carried out moulding and sintering.As auxiliary material, can use here and for example be rendered as the calcining spinelle that sintering promotes auxiliary phase.Than the calcining spinelle, calcining spinelle powder has much higher specific area, and therefore has more reactivity.
By using the material according to the invention mixture, the method according to this invention can prepare the fire-resistant formed body that conventional relatively fire-resistant formed body has the above advantage, service life that described advantage is particularly longer and longer assay intervals.
The moulding of plastic material can be undertaken by casting process especially, and vibrational casting (Vibrationsgie β en) is considered to optimal forming method.
Behind plastic material forming, preferably harden (Anbinden) carries out sintering process then.Sclerosis makes molded material to remove from mould before firing, thereby can use reusable mould.
Sintering preferably carries out in the temperature greater than 1550 ℃, thereby unreacted magnesia or alumina composition do not occur in finished product.
According to a third aspect of the invention we, provide the fire-resistant formed body that is used for the high-temperature gas reactor
It has the spinelle of containing and zirconic ceramic body (Keramikvolume).Ceramic body also comprises fine fraction and greater than the coarse component of 50 weight %.Coarse component comprises the coarse grain of size greater than 20 μ m, and fine fraction comprises the particulate of size less than 20 μ m.For example, coarse component comprises the coarse grain that is of a size of 20 μ m~6mm, is in particular 100 μ m~6mm.
Especially, can have magnesium aluminate spinels and/or sintering spinelle and/or fusion spinelle as coarse component in the present invention.Especially, can have zirconia as fine fraction.In addition, also can have magnesium aluminate spinels and/or sintering spinelle and/or fusion spinelle as fine fraction.
Preferably, fine fraction comprises the zirconia of 70~100 weight % magnesium aluminate spinels and 0~30 weight %.Magnesium aluminate spinels in coarse component and fine fraction all can contain the aluminium oxide of 66~78 weight % and the magnesia of 22~34 weight %.
Fire-resistant formed body according to the present invention has by its preparation method and the described advantage that is better than conventional fire-resistant formed body of material blends, and specifically, fire-resistant formed body according to the present invention has long service life and long assay intervals.
Other features of the present invention, performance and advantage will draw by the following exemplary embodiment and the description of accompanying drawing, wherein
Fig. 1 illustrates fire-resistant formed body.
Fig. 2 shows the flow chart of the inventive method that is used to prepare fire-resistant formed body.
Fig. 1 illustrates the heat shield element that gas-turbine combustion chamber is used, and it is as the example according to fire-resistant formed body of the present invention.Heat shield element 1 shown in Figure 1 has towards the hot side 3 of inside, combustion chamber, towards cold side 5 and four side faces 7 of combustion chamber supporting structure.Have groove 9 in two of outer peripheral face 7, its geometrical clamp that makes heat shield element 1 conform to stationary support becomes possibility.Naturally also can use other the fixation that need not use groove 9.For example, the cold side 5 of heat shield element 1 can be tightened on the supporting structure.
Magnesium aluminate spinels is in theory by the MgO of 28.2 weight % and the Al of 71.8 weight %
2O
3(corundum) formed, and in 2135 ℃ of fusings.Magnesium aluminate spinels can hold a large amount of aluminium oxide (Al when forming mixed crystal
2O
3), wherein magnesia (MgO) only is incorporated in the magnesium aluminate spinels when high temperature on a small quantity.Magnesium aluminate spinels only generates during greater than 1300 ℃ on a small quantity in temperature, and when temperature is higher than about 1550 ℃, just generate largely, industrial suitable concern be that volume increases about 5~15 volume % when the reaction of magnesia and aluminium oxide generates magnesium aluminate spinels.
Sintering spinelle, fusion spinelle and calcining spinelle exist aspect the contained raw material different, and form different, be rich in magnesian spinelle and have alumina content less than 71.8 weight %, the magnesium aluminate spinels that is rich in aluminium oxide has the alumina content greater than 71.8 weight %.
The spinel structure of magnesium aluminate spinels is insensitive to serious dislocation and a large amount of lattice deformation.Because the symmetry height, the spinelle lattice is highly stable.Because spinelle has better high temperature resistant and corrosion-resistance properties than caustic slag (basische Schlacke), so the spinelle particularly suitable is made refractory material.Spinelle has resistance to all metals except alkaline-earth metal, and corrosion has stronger corrosion resistance to alkali metal and spinelle is than corundum and chrome ore (Chromerz).According to document record, when chemical reaction does not take place during at the sulfate of about 1200 ℃ temperature contact sodium, potassium, lithium and calcium, disulfate, fluoride, chloride, carbonate and hydroxide pure magnesium aluminate spinels.
In this example, the ceramic material of heat shield element comprises and is of a size of 20 μ m~6mm, the coarse grain that is in particular 100 μ m~6mm and the size particulate less than 20 μ m.
The starting point of the inventive method is the material blends of the present invention that comprises spinelle and zirconium dioxide.This mixture comprises the coarse grain that is of a size of 20 μ m~6mm and the size particulate less than 20 μ m.In this example, fine fraction is magnesium aluminate spinels and zirconic mixture, and magnesium aluminate spinels accounts for 70~100 weight %, and zirconia accounts for 0~30 weight %.In the first step, in this material blends, add dispersant and the water (step 11) among Fig. 2.Next the gained mixture provides (weight quota is a percentage) with example again, the AR78 that wherein abridges represents to have 78% aluminium oxide and 22~23% magnesian spinelles, and abbreviation MR66 represents to have 66 weight % aluminium oxide and the magnesian magnesium-rich spinel of 32~33.5 weight %:
Then, mixture homogenizing 4 minutes (step 13), vibration injection metal mold (step 15) then in the Erich batch mixer.For fear of the too fast drying of the casting material that in mold, exists, mold the perfusion zone in by airtight sealing.Then casting material in mould in about 2 hours (step 17) of 40 ℃ of Ageing Treatment (auslagern).This will cause the casting material sclerosis and guarantee to generate the living embryo with follow-up moulding desirable strength.Give birth to embryo molded after, at first 20~60 ℃ temperature, then in dry again 30~50 hours (step 19) of 90~130 ℃ temperature.At last, giving birth to embryo fires greater than 3 hours (step 21) in the temperature that is higher than 1550 ℃.Zhi Bei ceramic heat shield element has the cold bending strength of about 15MPa and the dynamic modulus of elasticity of about 50GPa thus.
Following steps about the inventive method are particularly advantageous:
1. in order to make spinel cooperate boundary condition (Randbedingung) in the combustion chamber of stationary gas turbine aspect its elastic modelling quantity and thermal shock resistance, particularly advantageous is to add the most nearly pore former of 1 weight %.Various plastics (polypropylene, polyethylene, polystyrene (Styropor), polymethyl methacrylate (acryl glass (Acrylglas)) etc.) or native cellulose can be used as pore former (Porosierungsmittel).
2. anti-heat exchange property
Can be subjected to positive influences by the coarse component that increases spinel equally.Particularly advantageous is that coarse component is increased to scope at 54~70 weight %.
The described with reference to the accompanying drawings ceramic material that the invention provides thermal-shock resistance and corrosion resistance, this ceramic material are based on magnesium aluminate spinels, and it comprises the zirconium dioxide admixture, and are made of coarse grain and particulate.Can prepare the shaped article that is used for power industry, metallurgical industry, car industry, glass industry and ceramic industry and chemical industry or shaped article not by this ceramic material.It can be used as adiabatic heat shielding, the exchange sprue gate (Tauschausguss) in the metallurgical industry or the outlet nozzle in the gas turbine, the porous filter body in the hot gas filtration device (Hei β gasfiltration) etc.The corrosion resistance of this spinel is by avoiding (free or combination) SiO
2Interpolation and the least possible CaO content be significantly improved.
Claims (18)
1. be used to prepare the material blends of refractory material, it comprises spinelle and zirconia, and comprising fine fraction and greater than the coarse component of 50 weight %, wherein said coarse component comprises the coarse grain of size greater than 20 μ m, described fine fraction comprises the particulate of size less than 20 μ m.
2. material blends according to claim 1 wherein has magnesium aluminate spinels and/or sintering spinelle and/or fusion spinelle as coarse component.
3. according to claim 1 or the described material blends of claim 2, wherein have zirconia as fine fraction.
4. according to each described material blends in the claim 1~3, wherein have magnesium aluminate spinels and/or sintering spinelle and/or fusion spinelle as fine fraction.
5. material blends according to claim 4, wherein said fine fraction contain the magnesium aluminate spinels of 70~100 weight % and the zirconia of 0~30 weight %.
6. material blends according to claim 5, wherein said fine fraction contains the zirconia greater than 12 weight %.
7. each described material blends prepared the method for fire-resistant formed body during the use aforesaid right required, the auxiliary material that wherein adds at least a dispersant and/or at least a organic basis or inorganic basis in described material blends obtains plastic material, then this plastic material is carried out moulding and sintering.
8. method according to claim 7, wherein said auxiliary material are the calcining spinelles.
9. according to claim 7 or the described method of claim 8, wherein moulding is undertaken by casting.
10. method according to claim 9, wherein moulding is undertaken by vibrational casting.
11. according to each described method in the claim 7~10, wherein after making described plastic material forming, the material of this moulding of hardening carries out sintering then.
12. according to each described method in the claim 7~11, wherein sintering is higher than 1550 ℃ of generations in temperature.
13. according to each described method in the claim 7~12, it may further comprise the steps:
(1) thus the pore former spinel that adds 1 weight % the most nearly at its elastic modelling quantity and therefore be fit to boundary condition in the combustion chamber of stationary gas turbine aspect its thermal shock resistance,
(2) coarse component is increased to the scope of 54~70 weight %, thus the anti-heat exchange property of positive influences.
14., wherein use various plastics (polypropylene, polyethylene, polystyrene (Styropor), polymethyl methacrylate (acryl glass) etc.) or native cellulose as pore former according to each described method in the claim 7~13.
15. be used for the fire-resistant formed body of high-temperature gas reactor, it has the spinelle of comprising and zirconic ceramic body,
It is characterized in that it comprises fine fraction and greater than the coarse component of 50 weight %, wherein coarse component comprises that size comprises the particulate of size less than 20 μ m greater than coarse grain and the fine fraction of 20 μ m.
16. fire-resistant formed body according to claim 15,
It is characterized in that,
Have magnesium aluminate spinels and/or sintering spinelle and/or fusion spinelle as coarse component.
17., it is characterized in that zirconia exists as fine fraction according to claim 15 or the described fire-resistant formed body of claim 16.
18. fire-resistant formed body according to claim 17,
It is characterized in that,
Have magnesium aluminate spinels and/or sintering spinelle and/or fusion spinelle as fine fraction.
Applications Claiming Priority (3)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
EP08017130.9 | 2008-09-29 | ||
EP08017130A EP2169311A1 (en) | 2008-09-29 | 2008-09-29 | Material mixture for producing a fire-retardant material, fire-retardant moulding body and method for its manufacture |
PCT/EP2009/062172 WO2010034680A1 (en) | 2008-09-29 | 2009-09-21 | Material mixture for producing a fireproof material, fireproof molded body and method for the manufacturing thereof |
Publications (1)
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CN102227591A true CN102227591A (en) | 2011-10-26 |
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CN2009801474036A Pending CN102227591A (en) | 2008-09-29 | 2009-09-21 | Material mixture for producing fireproof material, fireproof molded body and method for manufacturing thereof |
Country Status (6)
Country | Link |
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US (1) | US8530364B2 (en) |
EP (2) | EP2169311A1 (en) |
JP (1) | JP5425204B2 (en) |
CN (1) | CN102227591A (en) |
RU (1) | RU2478874C2 (en) |
WO (1) | WO2010034680A1 (en) |
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CN103017195A (en) * | 2013-01-07 | 2013-04-03 | 陈志成 | Novel energy-saving and emission-reducing industrial combustion furnace |
CN108137412A (en) * | 2015-10-19 | 2018-06-08 | 欧洲技术研究圣戈班中心 | Zirconia-spinel melt granules and the refractory product obtained by the particle |
CN110062749A (en) * | 2016-12-08 | 2019-07-26 | 西门子股份公司 | Corrosion resistant ceramic material, powder, mud and component |
CN112537956A (en) * | 2019-09-23 | 2021-03-23 | 比亚迪股份有限公司 | Black zirconia ceramic and preparation method and application thereof |
CN114315347A (en) * | 2021-12-24 | 2022-04-12 | 武汉科技大学 | Barium zirconate/magnesium oxide composite ceramic material and preparation method thereof |
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EP2559678A1 (en) * | 2011-08-16 | 2013-02-20 | Siemens Aktiengesellschaft | Pressure-cast slip and fire-resistant ceramic for gas turbine assemblies produced using the same |
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FR3042497B1 (en) * | 2015-10-19 | 2021-12-31 | Saint Gobain Ct Recherches | MELTED GRAINS OF ZIRCONIA - SPINEL AND REFRACTORY PRODUCT OBTAINED FROM SAID GRAINS |
FR3042496B1 (en) * | 2015-10-19 | 2021-12-31 | Saint Gobain Ct Recherches | USE OF MELTED GRAINS OF ZIRCONIA - SPINEL FOR THE MANUFACTURE OF REFRACTORY PRODUCTS |
JP2019526737A (en) * | 2016-08-25 | 2019-09-19 | コーニング インコーポレイテッド | Segmented thermal barrier for internal combustion engine and method of manufacturing the same |
US20180327614A1 (en) * | 2017-05-09 | 2018-11-15 | Imam Abdulrahman Bin Faisal University | Method of repairing an acrylic denture base and zirconia autopolymerizable resins therof |
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CN114315347A (en) * | 2021-12-24 | 2022-04-12 | 武汉科技大学 | Barium zirconate/magnesium oxide composite ceramic material and preparation method thereof |
CN114315347B (en) * | 2021-12-24 | 2023-01-17 | 武汉科技大学 | Barium zirconate/magnesium oxide composite ceramic material and preparation method thereof |
Also Published As
Publication number | Publication date |
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US8530364B2 (en) | 2013-09-10 |
RU2478874C2 (en) | 2013-04-10 |
JP2012504088A (en) | 2012-02-16 |
EP2169311A1 (en) | 2010-03-31 |
RU2011117311A (en) | 2012-11-10 |
JP5425204B2 (en) | 2014-02-26 |
EP2329195B1 (en) | 2016-11-02 |
WO2010034680A1 (en) | 2010-04-01 |
EP2329195A1 (en) | 2011-06-08 |
US20110237420A1 (en) | 2011-09-29 |
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